US2059601A - Ultrashort wave receiving system - Google Patents
Ultrashort wave receiving system Download PDFInfo
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- US2059601A US2059601A US4472A US447235A US2059601A US 2059601 A US2059601 A US 2059601A US 4472 A US4472 A US 4472A US 447235 A US447235 A US 447235A US 2059601 A US2059601 A US 2059601A
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- detector
- circuit
- frequency
- high frequency
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03D—DEMODULATION OR TRANSFERENCE OF MODULATION FROM ONE CARRIER TO ANOTHER
- H03D9/00—Demodulation or transference of modulation of modulated electromagnetic waves
- H03D9/06—Transference of modulation using distributed inductance and capacitance
- H03D9/065—Transference of modulation using distributed inductance and capacitance by means of discharge tubes having more than two electrodes
Definitions
- This invention relates to improvements in ultra high frequency receiving circuits, and more particularly to such circuits wherein a detector operating on the Barkhausen principle is employed.
- Barkhausen is herein used broadly as being descriptive of any type of electron discharge device using a grid which is maintained at a high positive potential and an anode at a much lower potential with respect to the cathode, whereby oscillations of electrons about the grid may or may not be made to occur, depending upon the adjustment of the circuit constants and voltages.
- Barkhausen oscillators are subject to various disadvantages, since they are extremely sensitive to slight changes in voltages on the electrodes of the tubes, circuit constants, and aging of the tubes, in view of which it is frequently difficult to maintain control of the frequency of oscillations produced, amplitude of oscillation, and the proper conditions for maximum sensitivity.
- the present invention has for one of its objects to overcome these disadvantages in ultra short wave receivers employing Barkhausen detectors.
- Another object is to provide an ultra high frequency receiving circuit wherein the amplitude and frequency of the heterodyne oscillations can readily be controlled.
- a further object is to provide an ultra high frequency detector which is not especially critical to electrode potentials and currents and whose sensitivity can easily be adjusted to maximum.
- This last object may be achieved by making the circuit conditions and applied potentials such that they are not favorable to the occurrence of self-sustained ultra high frequency oscillations in the detector.
- the adjustment of the circuit may be likened to an ordinary regeneration control and for the purposes of this invention it may be said that the sensitivity of the detector is determined mainly by its regeneration. In other words, the detector is so tuned as not to oscillate, and the tendency to oscillate is caused by regeneration.
- the present invention comprises an ultra short wave receiver employing a separate stable and controllable source of heterodyne oscillations, such as a harmonic of a stable oscillator, the output of the heterodyne source being 1, 1935, Serial No. 4,472
- Barkhausen detector functions to give the desired intermediate frequency which is subsequently amplified and detected.
- a simple doublet antenna system l connected through coupling condensers 2 to the grid Il and anode i3 of an ultra highv frequency Barkhausen detector 4, the cathode of 215 which has a by-pass condenser 5 connected across its legs and a rheostat B for controlling the current therethrough.
- Oscillator Il is of the tuned plate, tuned grid type, and its desired harmonic is coupled via coil l2 to the cou-v pling condensers 2 from which it is fed with the signal to the ultra high frequency detector circuit.
- Heterodyne oscillator il may be any stable oscillator which has a suitable harmonic or fundamental frequency of the desired ultra high frequency value, which may be independently controlled, or controlled by the incoming signal. For example, such automatic frequency control can be effected, in known manner, by mechanical control of the tuning capacity derived from a phase shift detector as used in frequency modulation receivers.
- a U shaped circuit I3 which is grounded at its center and whose individuallegs are each approximately one quarter of the length of the signal wave, serves to eliminate undesired frequencies from the heterodyne oscillator as well as from the antenna.
- This circuit presents infinite impedance to the incoming Waves and much less impedance to the undesired 45 signal frequencies.
- the grid Il and anode I8 of the Barkhausen detector 4 are supplied with suitable potentials by batteries I4 and 9 in their respective potentiometer circuits over lecher wires 2
- Tunable condenser 3 is utilized for tuning the resonant period of the detector circuit to the incoming signal.
- Condenser 8 serves to ground the anode of detector 4 for radio frequency potentials.
- the intermediate frequency which is produced by combining the signal and beat frequencies in detector 4 is taken from the grid si-de of the ultra high frequency circuit and is coupled through coil I0 to intermediate frequency amplifier and detector I5, the output of which is utilized by the headphones I6, which typiiies any suitable utilization device.
- Intermediate frequency amplifier and detector I5 may take any one of several forms although it is preferred to employ a frequency modulation receiver of the type described in copen-ding application Serial No. 668,232, filed April 27, 1933, the only difference being in the adjustment of the tuning condenser 3 and the electrode potentials for operation.
- Condensers 2 also act as blocking condensers to prevent the batteries 9 and I4 from grounding through the U-shaped tuned c ircuit I3.
- the ultra high frequency circuit is tuned to the incoming signal by condenser 3 instead of to the heterodyne signal, there is obtained maximum response to the signal.
- the ultra high frequency circuit will be tuned to this incoming signal by condenser 3.
- Heterodyne source II is adjusted to give a suitable harmonic, for example, one whose frequency is 600 megacycles plus or minus 5 megacycles, the 5 megacycle value being the desired intermediate frequency.
- the heterodyne oscillation of 605 (or 595) megacycles will then be impressed on the ultra high frequency detector circuit in combination with the 600 megacycle signal.
- the grid, plate and cathode voltages of ultra high frequency detector 4 are then adjusted to give the best output of the combined signal and beating oscillation, which is the desire-d intermediate frequency of 5 megacycles.
- the intermediate frequency of 5 megacycles will then be amplied and detected at I5 and the output utilized by headphones I6.
- a detector using more than one ultra high frequency detector tube or rectifying element and having suitable associated circuits can be used in place of the one ultra-high frequency ldetector tube and circuit shown in the drawing.
- the detector tubes may be operated in a magnetic eld,
- the heterodyne oscillation and/or incoming signal may be applied to the detector by means of the given or additional electrodes in the tube, or by modulation of a magnetic field permeating the tube, and not necessarily in the manner shown.
- a dipole antenna for receiving the signal waves, a stable heterodyne oscillator for generating oscillations, to beat with the incoming signal waves coupled to said antenna, and an ultra high frequency non-oscillating detector for receiving the signal waves and heterodyne oscillations and for producing an intermediate frequency
- said detector comprising a tube having a grid, anode and cathode, adjustable means for maintaining said grid at a high positive potential and said anode at a much lower potential relative to said cathode, a pair of wires extending from said grid and anode to said means, connections from the arms of said dipole to said pair of wires, a variable condenser across said wires for tuning the ultra high frequency circuit including said wires to the frequency of the incoming signal waves, an intermediate frequency amplier and detector circuit coupled to that one of said wires which is connected tol said grid, and a condenser having one plate connected to ground and another plate connected to that wire which is connected to said an
- a dipole antenna for receiving the signal waves, a stable heterodyne oscillator for generating oscillations to beat with the incoming signal waves coupled to said antenna, and an ultra high frequency non-oscillating detector for receiving the signal waves and heterodyne oscillations and for pro'- ducing an intermediate frequency
- said detector comprising a tube having a grid, anode and cathode, adjustable means for maintaining said grid at a high positive potential and said anode at a much lower potential relative to said cathode, a pair of Wires extending from said grid and anode to said means, connections from the arms of said dipole to said pair of wires, a variable condenser across said wires for tuning the ultra high frequency circuit including said wires to a desired frequency, blocking condensers in the connections from said antenna arms to said wires, an intermediate frequency amplifier and detector circuit coupled to one of said wires and a condenser coupled to the other of said wires for grounding it for radio
- an antenna for receiving signal Waves
- a stable heterodyne oscillator for generating oscillations to beat with the incoming signal waves
- an ultra high frequency non-oscillating detector for receiving the signal waves and heterodyne oscillations and for producing an intermediate frequency
- said detector comprising a tube having a grid, anode, and cathode electrodes, means for maintaining said grid at a high positive potential and said anode at a much lower potential relative to said cathode, an intermediate frequency amplifier and detector circuit coupled to one of said electrodes of said nonoscillating detector, and a utilization device coupled to said intermediate frequency amplifier and detector circuit.
Description
NGV@ 3, W3@ H. o. PETERSON ET AL 2,959,693
ULTRASHORT WAVE RECEIVING SYSTEM l Filed Feb. l, 1935 'WWTORS HAROLD O.PETERSON RALPH W. EORGE ATTORNEY.
Patented Nov. 3, 1936 UNITED STATES PATENT OFFICE ULTRASHORT WAVE RECEIVING SYSTEM Application February 3 Claims.
This invention relates to improvements in ultra high frequency receiving circuits, and more particularly to such circuits wherein a detector operating on the Barkhausen principle is employed.
The term Barkhausen is herein used broadly as being descriptive of any type of electron discharge device using a grid which is maintained at a high positive potential and an anode at a much lower potential with respect to the cathode, whereby oscillations of electrons about the grid may or may not be made to occur, depending upon the adjustment of the circuit constants and voltages.
It is known that in receivers a self-oscillating ultra high frequency detector of the Barkhausen type may be used to provide a desired intermediate frequency. Barkhausen oscillators, however, are subject to various disadvantages, since they are extremely sensitive to slight changes in voltages on the electrodes of the tubes, circuit constants, and aging of the tubes, in view of which it is frequently difficult to maintain control of the frequency of oscillations produced, amplitude of oscillation, and the proper conditions for maximum sensitivity.
The present invention has for one of its objects to overcome these disadvantages in ultra short wave receivers employing Barkhausen detectors.
Another object is to provide an ultra high frequency receiving circuit wherein the amplitude and frequency of the heterodyne oscillations can readily be controlled.
A further object is to provide an ultra high frequency detector which is not especially critical to electrode potentials and currents and whose sensitivity can easily be adjusted to maximum. This last object may be achieved by making the circuit conditions and applied potentials such that they are not favorable to the occurrence of self-sustained ultra high frequency oscillations in the detector. The adjustment of the circuit may be likened to an ordinary regeneration control and for the purposes of this invention it may be said that the sensitivity of the detector is determined mainly by its regeneration. In other words, the detector is so tuned as not to oscillate, and the tendency to oscillate is caused by regeneration.
In brief, the present invention comprises an ultra short wave receiver employing a separate stable and controllable source of heterodyne oscillations, such as a harmonic of a stable oscillator, the output of the heterodyne source being 1, 1935, Serial No. 4,472
(Cl. Z50- 20) arranged to beat with the incoming oscillations. A Barkhausen detector functions to give the desired intermediate frequency which is subsequently amplified and detected.
A better understanding of the invention may 5 be had by referring to the following detailed description which is accompanied by a drawing illustrating, diagrammatically, a complete ultra short wave receiving system embodying the principles of the invention.
Referring to the single figure of the drawing, there is shown a simple doublet antenna system l connected through coupling condensers 2 to the grid Il and anode i3 of an ultra highv frequency Barkhausen detector 4, the cathode of 215 which has a by-pass condenser 5 connected across its legs and a rheostat B for controlling the current therethrough.
Attached to the transmission wires connecting the antenna l to the detector are a pair of` leads i9 which extend to coil l2 which is electromagnetically coupled to the output of a stable heterodyne oscillator ll. Oscillator Il is of the tuned plate, tuned grid type, and its desired harmonic is coupled via coil l2 to the cou-v pling condensers 2 from which it is fed with the signal to the ultra high frequency detector circuit. Heterodyne oscillator il may be any stable oscillator which has a suitable harmonic or fundamental frequency of the desired ultra high frequency value, which may be independently controlled, or controlled by the incoming signal. For example, such automatic frequency control can be effected, in known manner, by mechanical control of the tuning capacity derived from a phase shift detector as used in frequency modulation receivers.
A U shaped circuit I3, which is grounded at its center and whose individuallegs are each approximately one quarter of the length of the signal wave, serves to eliminate undesired frequencies from the heterodyne oscillator as well as from the antenna. This circuit, as is known, presents infinite impedance to the incoming Waves and much less impedance to the undesired 45 signal frequencies.
The grid Il and anode I8 of the Barkhausen detector 4 are supplied with suitable potentials by batteries I4 and 9 in their respective potentiometer circuits over lecher wires 2|, the latter of which are shunted by condenser 1. Tunable condenser 3 is utilized for tuning the resonant period of the detector circuit to the incoming signal. Condenser 8 serves to ground the anode of detector 4 for radio frequency potentials. 55
The intermediate frequency Which is produced by combining the signal and beat frequencies in detector 4 is taken from the grid si-de of the ultra high frequency circuit and is coupled through coil I0 to intermediate frequency amplifier and detector I5, the output of which is utilized by the headphones I6, which typiiies any suitable utilization device. Intermediate frequency amplifier and detector I5 may take any one of several forms although it is preferred to employ a frequency modulation receiver of the type described in copen-ding application Serial No. 668,232, filed April 27, 1933, the only difference being in the adjustment of the tuning condenser 3 and the electrode potentials for operation.
Since the ultra high frequency circuit is tuned to the incoming signal by condenser 3 instead of to the heterodyne signal, there is obtained maximum response to the signal.
In the operation of the circuit, assuming that the signal frequency is 600 megacycles, then the ultra high frequency circuit will be tuned to this incoming signal by condenser 3. Heterodyne source II is adjusted to give a suitable harmonic, for example, one whose frequency is 600 megacycles plus or minus 5 megacycles, the 5 megacycle value being the desired intermediate frequency. The heterodyne oscillation of 605 (or 595) megacycles will then be impressed on the ultra high frequency detector circuit in combination with the 600 megacycle signal. The grid, plate and cathode voltages of ultra high frequency detector 4 are then adjusted to give the best output of the combined signal and beating oscillation, which is the desire-d intermediate frequency of 5 megacycles. The intermediate frequency of 5 megacycles will then be amplied and detected at I5 and the output utilized by headphones I6.
This invention is not at all limited to the details of the described embodiment. A detector using more than one ultra high frequency detector tube or rectifying element and having suitable associated circuits, can be used in place of the one ultra-high frequency ldetector tube and circuit shown in the drawing. The detector tubes may be operated in a magnetic eld, The heterodyne oscillation and/or incoming signal may be applied to the detector by means of the given or additional electrodes in the tube, or by modulation of a magnetic field permeating the tube, and not necessarily in the manner shown.
The details of the external, tuned, ultra high frequency circuit are not limited to the embodiment described and this circuit might even possibly be eliminated.
What is claimed is:
l. In an ultra short Wave receiver, a dipole antenna for receiving the signal waves, a stable heterodyne oscillator for generating oscillations, to beat with the incoming signal waves coupled to said antenna, and an ultra high frequency non-oscillating detector for receiving the signal waves and heterodyne oscillations and for producing an intermediate frequency, said detector comprising a tube having a grid, anode and cathode, adjustable means for maintaining said grid at a high positive potential and said anode at a much lower potential relative to said cathode, a pair of wires extending from said grid and anode to said means, connections from the arms of said dipole to said pair of wires, a variable condenser across said wires for tuning the ultra high frequency circuit including said wires to the frequency of the incoming signal waves, an intermediate frequency amplier and detector circuit coupled to that one of said wires which is connected tol said grid, and a condenser having one plate connected to ground and another plate connected to that wire which is connected to said anode.
2. In an ultra short wave receiver, a dipole antenna for receiving the signal waves, a stable heterodyne oscillator for generating oscillations to beat with the incoming signal waves coupled to said antenna, and an ultra high frequency non-oscillating detector for receiving the signal waves and heterodyne oscillations and for pro'- ducing an intermediate frequency, said detector comprising a tube having a grid, anode and cathode, adjustable means for maintaining said grid at a high positive potential and said anode at a much lower potential relative to said cathode, a pair of Wires extending from said grid and anode to said means, connections from the arms of said dipole to said pair of wires, a variable condenser across said wires for tuning the ultra high frequency circuit including said wires to a desired frequency, blocking condensers in the connections from said antenna arms to said wires, an intermediate frequency amplifier and detector circuit coupled to one of said wires and a condenser coupled to the other of said wires for grounding it for radio frequency potentials, and a utilization device coupled to said intermediate frequency amplifier and detector circuit.
3. In an ultra short wave receiver, in combina tion, an antenna for receiving signal Waves, a stable heterodyne oscillator for generating oscillations to beat with the incoming signal waves, and an ultra high frequency non-oscillating detector for receiving the signal waves and heterodyne oscillations and for producing an intermediate frequency, said detector comprising a tube having a grid, anode, and cathode electrodes, means for maintaining said grid at a high positive potential and said anode at a much lower potential relative to said cathode, an intermediate frequency amplifier and detector circuit coupled to one of said electrodes of said nonoscillating detector, and a utilization device coupled to said intermediate frequency amplifier and detector circuit.
HAROLD O. PETERSON. RALPH W. GEORGE.
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US4472A US2059601A (en) | 1935-02-01 | 1935-02-01 | Ultrashort wave receiving system |
DER95397D DE704157C (en) | 1935-02-01 | 1936-02-02 | Ultra-short wave superposition receiver with separate mixing and superposition pipes |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US4472A US2059601A (en) | 1935-02-01 | 1935-02-01 | Ultrashort wave receiving system |
Publications (1)
Publication Number | Publication Date |
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US2059601A true US2059601A (en) | 1936-11-03 |
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ID=21710984
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US4472A Expired - Lifetime US2059601A (en) | 1935-02-01 | 1935-02-01 | Ultrashort wave receiving system |
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US (1) | US2059601A (en) |
DE (1) | DE704157C (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2478919A (en) * | 1943-07-17 | 1949-08-16 | Rca Corp | Pulse type multiplex communication system |
US2512614A (en) * | 1939-06-03 | 1950-06-27 | Int Standard Electric Corp | Frequency changing circuits particularly for the reception of ultrashort electromagnetic waves |
US2568090A (en) * | 1948-06-22 | 1951-09-18 | Raytheon Mfg Co | Balanced mixer |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE754631C (en) * | 1936-04-18 | 1952-12-15 | Lorenz C Ag | Ultra-short wave reception method with a magnetic field tube |
-
1935
- 1935-02-01 US US4472A patent/US2059601A/en not_active Expired - Lifetime
-
1936
- 1936-02-02 DE DER95397D patent/DE704157C/en not_active Expired
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2512614A (en) * | 1939-06-03 | 1950-06-27 | Int Standard Electric Corp | Frequency changing circuits particularly for the reception of ultrashort electromagnetic waves |
US2478919A (en) * | 1943-07-17 | 1949-08-16 | Rca Corp | Pulse type multiplex communication system |
US2568090A (en) * | 1948-06-22 | 1951-09-18 | Raytheon Mfg Co | Balanced mixer |
Also Published As
Publication number | Publication date |
---|---|
DE704157C (en) | 1941-03-24 |
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